Method for identifying marked content

ABSTRACT

Briefly, in accordance with one embodiment, a method of identifying marked content is described.

FIELD

This application is related to classifying or identifying content, such as marked content, for example.

BACKGROUND

In recent years digital data hiding has become an active research field. Various kinds of data hiding methods have been proposed. Some methods aim at content protection, and/or authentication, while some aim at covert communication. The latter category of data hiding is referred to here as steganography.

BRIEF DESCRIPTION OF THE DRAWINGS

Subject matter is particularly pointed out and distinctly claimed in the concluding portion of the specification. Claimed subject matter, however, both as to organization and method of operation, together with objects, features, and/or advantages thereof, may best be understood by reference of the following detailed description if read with the accompanying drawings in which:

FIG. 1 is a schematic diagram illustrating one embodiment of a predication error model as applied to content, such as an image.

DETAILED DESCRIPTION

In the following detailed description, numerous specific details are set forth to provide a thorough understanding of claimed subject matter. However, it will be understood by those skilled in the art that claimed subject matter may be practiced without these specific details. In other instances, well known methods, procedures, components and/or circuits have not been described in detail so as not to obscure claimed subject matter.

Some portions of the detailed description which follow are presented in terms of algorithms and/or symbolic representations of operations on data bits and/or binary digital signals stored within a computing system, such as within a computer and/or computing system memory. These algorithmic descriptions and/or representations are the techniques used by those of ordinary skill in the data processing arts to convey the substance of their work to others skilled in the art. An algorithm is here, and generally, considered to be a self-consistent sequence of operations and/or similar processing leading to a desired result. The operations and/or processing may involve physical manipulations of physical quantities. Typically, although not necessarily, these quantities may take the form of electrical and/or magnetic signals capable of being stored, transferred, combined, compared and/or otherwise manipulated. It has proven convenient, at times, principally for reasons of common usage, to refer to these signals as bits, data, values, elements, symbols, characters, terms, numbers, numerals and/or the like. It should be understood, however, that all of these and similar terms are to be associated with appropriate physical quantities and are merely convenient labels. Unless specifically stated otherwise, as apparent from the following discussion, it is appreciated that throughout this specification discussions utilizing terms such as “processing”, “computing”, “calculating”, “determining” and/or the like refer to the actions and/or processes of a computing platform, such as a computer or a similar electronic computing device, that manipulates and/or transforms data represented as physical electronic and/or magnetic quantities and/or other physical quantities within the computing platform's processors, memories, registers, and/or other information storage, transmission, and/or display devices.

In recent years digital data hiding has become an active research field. Various kinds of data hiding methods have been proposed. Some methods aim at content protection, and/or authentication, while some aim at covert communication. The latter category of data hiding is referred to in this context as steganography.

In J. Fridrich, M. Goljan and D. Hogea, “Steganalysis of JPEG Images: Breaking the F5 algorithm”, 5th Information Hiding Workshop, 2002, pp. 310-323, (hereinafter “Fridrich et al.”), Fridrich et al. have shown that the number of zeros in a block DCT domain of a stego-image will increase if the F5 embedding method is applied to generate the stego-image. This feature may be used to determine whether hidden messages have been embedded with the F5 method in content, for example. There are other findings regarding steganalysis of particularly targeted data hiding methods. See, for example, J. Fridrich, M. Goljan and R. Du, “Detecting LSB steganography in color and gray-scale images”, Magazine of IEEE Multimedia Special Issue on Security, October-November 2001, pp. 22-28; and R. Chandramouli and N. Memon, “Analysis of LSB based image steganography techniques”, Proc. of ICIP 2001, Oct. 7-10, 2001.

In S. Lyu and H. Farid, “Detecting Hidden Messages Using Higher-Order Statistics and Support Vector Machines,” 5th International Workshop on Information Hiding, Noordwijkerhout, The Netherlands, 2002 (hereinafter, “Lyu and Farid”), Lyu and Farid proposed a more general steganalysis method based at least in part on image high order statistics, derived from image decomposition with separable quadrature mirror filters. The wavelet high-frequency subbands' high order statistics are extracted as features for steganalysis in this approach. Likewise, this approach has been shown differentiate stego-images from cover images with a certain success rate. Data hiding methods addressed by this particular steganalysis primarily comprise least significant bit-plane (LSB) modification type steganographic tools.

In K. Sullivan, U. Madhow, S. Chandrasekaran, and B. S. Manjunath, “Steganalysis of Spread Spectrum Data Hiding Exploiting Cover Memory”, SPIE 2005, vol. 5681, pp 38-46, (hereinafter, “Sullivan et al.”) a steganalysis method based at least in part on a hidden Markov model is proposed. The empirical transition matrix of a test image is formed in such an approach. However, the size of the empirical transition matrix is large, e.g., 65536 elements for a grey level image with a bit depth of 8. Thus, the matrix is not used as features directly. The authors select several largest probabilities along the main diagonal together with their neighbors, and randomly select some other probabilities along the main diagonal as features. Unfortunately, some useful information might be ignored due at least in part to the random fashion of feature formulation. The data hiding methods addressed by Sullivan et al. related primarily to spread spectrum (SS) data hiding methods. Although these latter methods may not carry as much information bits as LSB methods in general, SS methods may be used in connection with covert communications, for example. In addition, SS methods are known to be more robust than LSB methods. Therefore, it is desirable to consider SS methods for steganalysis.

One embodiment of a steganalysis system based at least in part on a 2-D Markov chain of thresholded prediction-error sets for content, such as images, for example, is described below, although claimed subject matter is not limited in scope in this respect. In this particular embodiment, content samples, such as, for example, image pixels, are predicted with their neighboring pixels, and a prediction-error image, for example, is generated by subtracting the prediction value from the pixel value and thresholding. Empirical transition matrixes along the horizontal, vertical and diagonal directions of Markov chains may, in such an embodiment serve as features for steganalysis. Analysis of variance type approaches, such as, for example, support vector machines (SVM) or genetic processes, may be applied for classification or identification, although, again, claimed subject matter is not limited in scope in this respect.

Continuing with this particular embodiment, although claimed subject matter is not limited in scope to only one embodiment, a steganalysis system based at least in part on a Markov chain model of thresholded prediction-error images may be applied. Image pixels are predicted with the neighboring pixels. Prediction error in this particular embodiment is obtained by subtracting the prediction values from the pixel value. Though the range of the difference values is increased, the majority of the difference values may be concentrated in a relatively small range near zero owing to a correlation between neighboring pixels in unmarked images. In this context, the term marked content refers to content in which data has been hidden so that it is not apparent that the content contains such hidden information. Likewise, unmarked or cover content refers to content in which data has not been hidden. Large values in a prediction-error image, however, may be attributed at least in part to image content rather than data hiding. Therefore, a threshold applied to prediction error may reduce or remove large values in the prediction error images, thus limiting the dynamic range of a prediction-error image.

In this particular embodiment, although claimed subject matter is not limited in scope in this respect, prediction-error images may be modeled using a Markov chain. An empirical transition matrix is calculated and serves as features for steganalysis. Owing at least in part to thresholding, the size of empirical transition matrixes is decreased to a manageable size for classifiers so that probabilities in the matrixes may be included in feature vectors. For feature classification, an analysis of variance or other statistical approach may be applied. For example, an SVM process may be applied with both linear and non-linear kernels used for classification, as described in more detail below. In this context, the term “analysis of variance process” refers to a process in which differences attributable to statistical variation are sufficiently distinguished from differences attributable to non-statistical variation that correlation, segmentation, analysis, classification or other characterization of the data based at least in part on such a process may be performed.

While the term steganalysis may have a variety of meanings, for the purpose of this particular embodiment, it refers to a two-class pattern classification approach. For example, a test image may be classified as either a cover image, namely, information is not hidden in it, or a stego-image or marked image, which carries hidden data or hidden messages. Generally, in this particular approach or embodiment, the classification comprises two parts, although claimed subject matter is not limited in scope to employing only two classifications. Other approaches are possible and are included within the scope of claimed subject matter. Here, these parts are referred to as feature extraction and pattern classification, respectively. In many instances, it would be desirable to use the image itself for features in this process due at least in part to the large amount of information it contains. However, likewise, from a feasibility standpoint, the dimensionality of features may be too high for most classifiers. Therefore, feature extraction may be applied.

For computer vision type situations, it may be desirable for the feature to represent the shape and color of an object. For this particular embodiment, in contrast, other properties may provide useful information. In steganalysis, for example, it is desirable to have a feature contain information about changes incurred by data hiding as opposed to information about the content of the image.

Generally speaking, unmarked images, for example, may tend to exhibit particular properties, such as continuous, smooth, and having a correlation between neighboring pixels. Likewise, hidden data may be independent of the content itself. A watermarking process, for example, may change continuity with respect to the unmarked content because it may introduce some amount of random variation, for example. As a result, it may reduce correlation among adjacent pixels, bit-planes and image blocks. In this particular embodiment, it would be desirable if this potential variation that may be attributed to data hiding is amplified. This may be accomplished by anyone of a number of possible approaches and claimed subject matter is not limited in scope to a particular approach. However, below, one particular embodiment for accomplishing this is described.

In this particular embodiment, neighboring pixels may be used to predict the current pixel. For this embodiment, the predictions may be made in three directions. Again, for this embodiment, these directions include horizontal, vertical and diagonal, although in other embodiments other directions are possible. For a prediction, prediction error may be estimated or obtained by subtracting a predicted pixel value from a original pixel value as shown in (1),

e _(h)(i, j)=x(i+1, j)−x(i, j)

e _(v)(i, j)=x(i, j+1)−x(i, j)

e _(d)(i, j)=x(i+1, j+1)−x(i, j)   (1)

where e_(h)(i, j) indicates prediction error for pixel (i, j) along a horizontal direction, e_(v)(i, j) indicates prediction error for pixel (i, j) along a vertical direction and e_(d)(i, j) indicates prediction error for pixel (i, j) along a diagnol direction, respectively. For a pixel of an image, we therefore estimate three prediction errors in this embodiment. At this point, prediction errors will form three prediction-error images denoted here by E_(h), E_(v) and E_(d), respectively.

It is observed that potential distortions introduced by data hiding may usually be small compared with differences along pixels associated with, for example, the presence of different objects in an image. Otherwise, distortion itself may suggest hidden data if inspected by human eyes, thus potentially undermining the covert communication. Therefore, large prediction errors may tend to reflect more with respect to image content rather than hidden data. For this particular embodiment, to address this, a threshold T may be adopted the prediction errors may be adjusted according to the following rule:

$\begin{matrix} {{e\left( {i,j} \right)} = \left\{ \begin{matrix} {e\left( {i,j} \right)} & {{{e\left( {i,j} \right)}} \leq T} \\ 0 & {{{e\left( {i,j} \right)}} > T} \end{matrix} \right.} & (2) \end{matrix}$

It is noted of course, that claimed subject matter is not limited in scope to this particular approach. Many other approaches to address the predication error are possible and intended to be included within the scope of claimed subject matter. Likewise, T depending, for example, on the particular embodiment, may not comprise a fixed value. For example, it may vary with time, location, and a host of other potential factors.

Nonetheless, continuing with this example, large prediction errors may be treated as 0. In other words, image pixels or other content samples may be regarded as smooth from the data hiding point of view. Continuing with this specific example, the value range of a prediction-error image is [−T, T], with 2*T+1 possible values.

Likewise, for this embodiment, a 2-D Markov chain model is applied to the thresholded prediction error images, rather than 1-D, for example. FIG. 1( a) is a schematic diagram illustrating an embodiment of transition model for horizontal prediction-error image E_(h), in which a Markov chain is modeled along the horizontal direction, for example. FIG. 1( b) and FIG. 1( c) are schematic diagrams illustrating corresponding embodiments for E_(v) and E_(d,) respectively. As suggested previously, and explained in more detail below, elements of the empirical transition matrices for E_(h), E_(v) and E_(d) in this embodiment are employed as features. In FIG. 1, one circle represents one pixel. The diagrams show an image of size 8 by 8. The arrows represent the state change in a Markov chain.

A variety of techniques are available to analyze data in a variety of contexts. In this context, we use the term “analysis of variance process” to refer to processes or techniques that may be applied so that differences attributable to statistical variation are sufficiently distinguished from differences attributable to non-statistical variation to correlate, segment, classify, analyze or otherwise characterize the data based at least in part on application of such processes or techniques. Examples, without intending to limit the scope of claimed subject matter includes: artificial intelligence techniques and processes; neutral networks; genetic processes; heuristics; and support vector machines (SVM).

Although claimed subject matter is not limited in scope to SVM or SVM processes, it may be a convenient approach for two-class classification. See, for example, C. Cortes and V. Vapnik, “Support-vector networks,” in Machine Learning, 20, 273-297, Kluwer Academic Publishers, 1995. SVM may, for example, be employed to handle linear and non-linear cases or situations. For linearly separable cases, for example, an SVM classifier may be applied to search for a hyper-plane that separates a positive pattern from a negative pattern. For example, one may denote training data pairs {y_(i), ω_(i)}, i=1, . . . , l, where y_(i) is a feature vector, and ω_(i)=±1 for positive/negative pattern.

For this particular embodiment, linear support vector processes may be formulated as follows. If a separating hyper-plane exists, training data satisfies the following constraints:

w ^(t) y _(i) +b≧1 if ω_(l)=+1   (3)

w ^(t) y _(i) +b≦−1 if ω_(i)=−1   (4)

A Lagrangian formulation may likewise be constructed as follows:

$\begin{matrix} {L = {{\frac{1}{2}{w}^{2}} - {\sum\limits_{i = 1}^{l}{\alpha_{i}{y_{i}\left( {{x_{i} \cdot w} + b} \right)}}} + {\sum\limits_{i = 1}^{l}\alpha_{i}}}} & (5) \end{matrix}$

where α_(i) is the positive Lagrange multiplier introduced for inequality constraints, here (3) & (4). The gradient of L with respect to w and b provides:

$\begin{matrix} {w = {{\sum\limits_{i = 1}^{l}{\alpha_{i}y_{i}\omega_{i}\mspace{14mu} {and}\mspace{14mu} b}} = {\frac{1}{l}{\sum\limits_{i = 1}^{t}\left( {\omega_{i} - {w^{t}y_{i}}} \right)}}}} & (6) \end{matrix}$

In this embodiment, by training an SVM classifier, a sample z from testing data may be classified using w and b. For example, in one embodiment, if

w^(t)z+b

is greater than or equal to zero, the image may be classified as having a hidden message. Otherwise, it may be classified as not containing a hidden message. Of course, this is a particular embodiment and claimed subject matter is not limited in scope in this respect. For example, conventions regarding positive, negative or functional form may vary depending on a variety of factors and situations.

For a non-linearly separable case, a “learning machine” may map input feature vectors to a higher dimensional space in which a linear hyper-plane may potentially be located. In this embodiment, a transformation from non-linear feature space to linear higher dimensional space may be performed using a kernel function. Examples of kernels include: linear, polynomial, radial basis function and sigmoid. For this particular embodiment, a linear kernel may be employed in connection with a linear SVM process, for example. Likewise, other kernels may be employed in connection with a non-linear SVM process.

Having formulated an embodiment system for identifying or classifying marked content, such as images, for example, it is desirable to construct and evaluate performance. However, again, we note that this is merely a particular embodiment for purposes of illustration and claimed subject matter is not limited in scope to this particular embodiment or approach.

For evaluation purposes, 2812 images were downloaded from the website of Vision Research Lab, University of California, Santa Barbara, see http://vision.ece.ucsb.edu/˜sullivak/Research_imgs/, and 1096 sample images included in the CorelDRAW Version 10.0 software CD #3, see www.corel.com. Thus, 3908 images were employed as a test image dataset. Color images were converted to grey level images applying an Irreversible Color Transform, such as illustrated by (7) below, see, for example, M. Rabbani and R. Joshi, “An Overview of the JPEG2000 Still Image Compression Standard”, Signal Processing: Image Communication 17 (2002) 3-48:

Y=0.299R+0.587G+0.114B   (7)

Typical data hiding methods were applied to the images, such as: Cox et al.'s non-blind SS data hiding method, see I. J. Cox, J. Kilian, T. Leighton and T. Shamoon, “Secure spread spectrum watermarking for multimedia,” IEEE, Trans. on Image Processing, 6, 12, 1673-1687, (1997); Piva et al.'s blind SS, see A. Piva, M. Barni, E. Bartolini, V. Cappellini, “DCT-based watermark recovering without resorting to the uncorrupted original image”, Proc. ICIP 97, vol. 1, pp. 520; and a generic quantization index modulation (QIM) data hiding method, see B. Chen and G. W. Wornell, “Digital watermarking and information embedding using dither modulation,” Proceedings of IEEE MMSP 1998, pp 273-278. I. S, (here with a step size of 5 and an embedding rate of 0.1 bpp), and generic LSB.

For these data hiding methods, different random or quasi-random signals were embedded into different images. For generic LSB data hiding, embedding positions were randomly selected for different images. Therefore, this approach may be applied to steganographic tools that use LSB as the message embedding method. Various data embedding rates ranging from 0.3 bpp to as low as 0.01 bpp were applied. This range of embedding rates is comparable to that reported in the aforementioned Lye and Farid for those LSB based stego tools. However, this evaluation might be considered more general due at least in part to embedding position selection.

In this particular experimental evaluation, the threshold T was set to be 4, although, as previously indicated, claimed subject matter is not limited in scope to a fixed threshold value, or an integer value as well. Effective prediction error values in this example range from [−4 to 4], with 9 different values in total. Therefore, the dimension of the transition matrix is 9 by 9, which is 81 features for an error image. Since we have three error images in three different directions, the number of total features is 243 for an image in this particular example, although, again, claimed subject matter is not limited in scope in this respect.

For an image in the image database, stego-images with the above-mentioned data hiding methods were generated. The system was evaluated in turn with the data hiding methods discussed above. A randomly or quasi-randomly selected half of the original set images, and the corresponding stego-images, were used for training. The remaining pairs of original and corresponding stego-images were put through the trained SVM, in this embodiment, to evaluate performance. Here, the detection rate is defined as the ratio of the number of correctly classified images with respect to the number of test images. A test approach was applied 20 times. The following experimental data represents an average of the applications for a test.

Initially, a linear SVM process was applied. Linear SVM has an advantage of relatively fast training. However, it may not perform as well for non-linearly separable patterns. The Matlab SVM code from LIBSVM was used, see C. C. Chang and C. J. Lin, LIBSVM: a library for support vector machines, 2001, http://www.csie.ntu.edu.tw/˜cjlin/libsvm. Table 1 provides the test results.

TABLE 1 Embedding Detection Rates (243D feature, Linear SVM) Method TN TP Average Cox's SS 72.51% 88.65% 80.58% Piva's SS 81.68% 95.46% 88.57% QIM (0.1 bpp) 88.66% 99.97% 94.32% LSB (0.3 bpp) 88.84% 96.98% 92.91% LSB (0.2 bpp) 83.98% 92.56% 88.27% LSB (0.1 bpp) 74.57% 79.97% 77.27% LSB (0.05 bpp) 64.30% 64.34% 64.32% LSB (0.02 bpp) 54.39% 54.62% 54.51% LSB (0.01 bpp) 48.11% 53.78% 50.94% In Table 1, “TN” stands for “True Negative”, here, the detection rate of original cover images. “TP” stands for “True Positive”, here, the detection rate of stego-images. “Average” is the arithmetic mean of these two rates. In other words, it is the overall correct classification rate for all test images.

The Markov chain based method described in Sullivan et al. was applied ito the same set of images and the same data hiding methods. The same training and testing procedures were used. The results are listed in Table 2. This data illustrates that, for this example, the embodiment shown outperforms the method from Sullivan et al., in particular, for LSB methods.

TABLE 2 Embedding Detection Rates (129D feature, Linear SVM) Method TN TP Average Cox's SS 86.64% 64.98% 75.81% Piva's SS 71.34% 81.34% 76.34% QIM (0.1 bpp) 91.43% 90.07% 90.75% LSB (0.3 bpp) 56.69% 74.66% 65.68% LSB (0.2 bpp) 51.24% 69.07% 60.15% LSB (0.1 bpp) 45.11% 62.34% 53.73% LSB (0.05 bpp) 42.25% 58.33% 50.29% LSB (0.02 bpp) 39.17% 56.94% 48.05% LSB (0.01 bpp) 41.69% 52.68% 47.19%

Likewise, in another evaluation, a polynomial kernel was employed train the 243-D features and the 129-D features from above. The results are listed in Table 3 and Table 4, respectively. Here, in this example, this particular embodiment has a True Positive rate of over 90% for Cox's SS, Piva's blind SS, QIM and LSB with embedding strength over 0.1 bpp. Embedded data here comprises images with sizes ranging from 32×32 to 194×194. Corresponding embedding data rates are from 0.02 bpp to 0.9 bpp and detection rates range from 1.9% to 78%. Thus, compared with the results reported in Lyu and Farid, this particular embodiment appears to outperforms the approach shown in Lyu and Farid.

TABLE 3 Embedding Detection Rates (243D feature, Poly SVM) Method TN TP Average Cox's SS 84.14% 94.16% 89.15% Piva's SS 89.81% 98.40% 94.10% QIM (0.1 bpp) 94.14% 99.91% 97.03% LSB (0.3 bpp) 96.27% 99.24% 97.75% LSB (0.2 bpp) 91.80% 97.09% 94.45% LSB (0.1 bpp) 83.69% 88.90% 86.30% LSB (0.05 bpp) 72.10% 78.18% 75.14% LSB (0.02 bpp) 57.92% 61.01% 59.46% LSB (0.01 bpp) 52.05% 52.51% 52.28%

TABLE 4 Embedding Detection Rates (129D feature, Poly SVM) Method TN TP Average Cox's SS 80.54% 74.67% 77.60% Piva's SS 70.07% 85.10% 77.58% QIM (0.1 bpp) 90.20% 93.73% 91.96% LSB (0.3 bpp) 56.88% 81.09% 68.98% LSB (0.2 bpp) 48.21% 74.05% 61.13% LSB (0.1 bpp) 37.16% 62.47% 49.82% LSB (0.05 bpp) 33.33% 55.44% 44.38% LSB (0.02 bpp) 33.41% 48.21% 40.81% LSB (0.01 bpp) 35.88% 43.21% 39.54%

It will, of course, be understood that, although particular embodiments have just been described, the claimed subject matter is not limited in scope to a particular embodiment or implementation. For example, one embodiment may be in hardware, such as implemented to operate on a device or combination of devices, for example, whereas another embodiment may be in software. Likewise, an embodiment may be implemented in firmware, or as any combination of hardware, software, and/or firmware, for example. Likewise, although claimed subject matter is not limited in scope in this respect, one embodiment may comprise one or more articles, such as a storage medium or storage media. This storage media, such as, one or more CD-ROMs and/or disks, for example, may have stored thereon instructions, that when executed by a system, such as a computer system, computing platform, or other system, for example, may result in an embodiment of a method in accordance with claimed subject matter being executed, such as one of the embodiments previously described, for example. As one potential example, a computing platform may include one or more processing units or processors, one or more input/output devices, such as a display, a keyboard and/or a mouse, and/or one or more memories, such as static random access memory, dynamic random access memory, flash memory, and/or a hard drive. For example, a display may be employed to display one or more queries, such as those that may be interrelated, and or one or more tree expressions, although, again, claimed subject matter is not limited in scope to this example.

In the preceding description, various aspects of claimed subject matter have been described. For purposes of explanation, specific numbers, systems and/or configurations were set forth to provide a thorough understanding of claimed subject matter. However, it should be apparent to one skilled in the art having the benefit of this disclosure that claimed subject matter may be practiced without the specific details. In other instances, well known features were omitted and/or simplified so as not to obscure the claimed subject matter. While certain features have been illustrated and/or described herein, many modifications, substitutions, changes and/or equivalents will now occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and/or changes as fall within the true spirit of claimed subject matter. 

1-6. (canceled)
 7. A method of classifying content of at least one image comprising: applying a trained analysis of variance process to said at least one image, wherein the trained analysis of variance process is trained based on forming multiple prediction error sets from neighboring samples of a set of known images; classifying the content of said at least one image based at least in part on the value obtained from application of the trained analysis of variance process.
 8. The method of claim 7, wherein said trained analysis of variance process comprises a trained support vector machine (SVM) process.
 9. (canceled)
 10. The method of claim 8, wherein said trained analysis of variance process is based at least in part on thresholded prediction error images. 11-21. (canceled)
 22. A non-transitory computer-readable medium having computing device executable instructions stored thereon, the instructions comprising instructions for: applying a trained analysis of variance process to at least one image, wherein the trained analysis of variance process being trained based on forming multiple prediction error sets from neighboring samples of a set of known images; and classifying the content of said at least one image based at least in part on the value obtained from application of the trained analysis of variance process.
 23. The medium of claim 22, wherein said instructions for applying said trained analysis of variance process comprise instructions for applying a trained support vector machine (SVM) process.
 24. (canceled)
 25. The medium of claim 23, wherein said instructions for applying said trained analysis of variance process are based at least in part on thresholded prediction error images. 26-29. (canceled)
 30. An apparatus comprising: means for applying a trained analysis of variance process to at least one image, wherein said trained analysis of variance process is trained based on forming multiple prediction error sets from neighboring samples of a set of known images; and means for classifying the content of said at least one image based at least in part on the value obtained from application of the trained analysis of variance process.
 31. The apparatus of claim 30, wherein said means for applying trained analysis of variance process comprises means for applying a trained SVM process.
 32. (canceled)
 33. The apparatus of claim 31, wherein said means for applying a trained SVM process is based at least in part on thresholded prediction error images.
 34. The method of claim 7, wherein the applying a trained analysis of variance process to said at least one image comprises deriving prediction error sets based on sets of neighboring samples of the said at least one image.
 35. The medium of claim 22, wherein the instructions for applying a trained analysis of variance process to said at least one image comprises instructions for deriving prediction error sets based on sets of neighboring samples of the said at least one image.
 36. The apparatus of claim 30, wherein the means for applying the trained analysis of variance process to said at least one image comprises means for deriving prediction error sets based on sets of neighboring samples of the said at least one image. 